Triphenylmethanol Explained

Triphenylmethanol (also known as triphenylcarbinol and TrOH) is an organic compound. It is a white crystalline solid that is insoluble in water and petroleum ether, but well soluble in ethanol, diethyl ether, and benzene. In strongly acidic solutions, it produces an intensely yellow color, due to the formation of a stable "trityl" carbocation. Many derivatives of triphenylmethanol are important dyes.

History

After the German chemist August Kekulé and his Belgian student Antoine Paul Nicolas Franchimont (1844–1919) first synthesized triphenylmethane in 1872,^[1] the Russian doctoral student Walerius Hemilian (1851–1914) first synthesized triphenylmethanol in 1874 by reacting triphenylmethyl bromide with water as well as by oxidizing triphenylmethane.^[2]

Structure and properties

Triphenylmethanol features three phenyl (Ph) rings and an alcohol group bound to a central tetrahedral carbon atom. All three C–Ph bonds are typical of sp³-sp² carbon-carbon bonds with lengths of approximately 1.47 Å, while the C–O bond length is approximately 1.42 Å.^[3]

The presence of three adjacent phenyl groups confers special properties manifested in the reactivity of the alcohol. For example it reacts with acetyl chloride, not to give the ester, but triphenylmethyl chloride:

Ph₃COH + MeCOCl → Ph₃CCl + MeCO₂H

The three phenyl groups also offer steric protection. Reaction with hydrogen peroxide gives an unusually stable hydroperoxide, Ph₃COOH.^[4]

Acid-base properties

As a derivative of methanol, triphenylmethanol is expected to have a pK_a in the range of 16-19. Typical of alcohols, resonance offers no stabilization of the conjugate base due to being bonded to a saturated carbon atom. Stabilization of the anion by solvation forces is largely ineffective due to the steric influence of the three phenyl groups.

The basicity of triphenylmethanol is enhanced due to the formation of a resonance-stabilized carbocation upon breaking of the C–O bond. After protonation of the oxygen under strongly acidic conditions, triphenylmethanol loses water to form the triphenylmethyl ("trityl") cation:

Ph₃COH + H⁺ → Ph₃C⁺ + H₂O The trityl cation is one of the easiest carbocations to isolate, although it quickly reacts with water.

Synthesis

The preparation of triphenylmethanol from methyl benzoate or benzophenone and phenylmagnesium bromide is a common laboratory experiment for illustrating the Grignard reaction. An alternative starting material is diethyl carbonate.^[5]

Applications

Although not of major industrial importance, triphenylmethanol is a useful reagent in the research laboratory. Substituted derivatives of triphenylmethanol are intermediates in the production of the commercially useful triarylmethane dyes.

Notes and References

1. Aug. Kekulé and A. Franchimont (1872) "Ueber das Triphenylmethan" (On triphenylmethane), Berichte der deutschen chemischen Gesellschaft, 5 : 906-908.
2. W. Hemilian (1874) "Synthese des Triphenylmethans und des Methyl-phenyl-diphenylmethans" (Synthesis of triphenylmethane and of methyl-phenyl-diphenylmethane), Berichte der deutschen chemischen Gesellschaft, 7 : 1203–1210 ; see pp. 1206–1207.
3. 10.1107/S2053229619010714. Deciphering the Hydrogen-Bonding Scheme in the Crystal Structure of Triphenylmethanol: A Tribute to George Ferguson and Co-workers. 2019. Rodríguez Tzompantzi. Tomasa. Amaro Hernández. Aldo Guillermo. Meza-León. Rosa Luisa. Bernès. Sylvain. Acta Crystallographica Section C: Structural Chemistry. 75. 9. 1266–1273. 31484815. 6727172. 2019AcCrC..75.1266R .
4. Bryant E. Rossiter and Michael O. Frederick "Triphenylmethyl Hydroperoxide" E-EROS Encyclopedia of Reagents for Organic Synthesis, 2013.
5. The GC–MS Observation of Intermediates in a Stepwise Grignard Addition Reaction . Latimer, Devin . . 2007 . 84 . 699 . 10.1021/ed084p699 . 4. 2007JChEd..84..699L.